Wear of a Fe2.5Ni2.5CrAl Multiprincipal Element Alloy: A Combined Experimental and Molecular Dynamics Study

Keyphrases

• Molecular Dynamics Study 100%
• Stacking Faults 100%
• Experimental Dynamics 100%
• Wear Mechanism 100%
• Multi-principal Element Alloys 100%
• Dislocation Mechanisms 50%
• Dry Sliding Wear 50%
• Cluster Faults 50%
• Dry Sliding Test 50%
• Wear Performance 50%
• Delamination 50%
• High Oxygen Content 50%
• Abrasive Wear 50%
• Strain Structure 50%
• Stress Release 50%
• Shear Strain 50%
• Atomic Stacking 50%
• High Temperature Wear Resistance 50%
• Superplasticity 50%
• Friction Behavior 50%
• Indentation 50%
• Release Process 50%
• Nanowear 50%
• Friction Wear 50%
• Wear Debris 50%
• Lattice Structure 50%
• Dislocation Structure 50%
• Average Friction Coefficient 50%
• Engineering Application 50%
• Wear Behavior 50%
• Atomic Clusters 50%
• Wear Volume Loss 50%
• Friction Performance 50%
• Worn Surface Morphology 50%
• Adhesive Wear 50%
• Abrasive 50%
• Atomic Stress 50%
• High Strength 50%
• Oxidative Wear 50%

Engineering

• Alloy Element 100%
• Computer Simulation 100%
• Wear Debris 50%
• Engineering Application 50%
• Shockley 50%
• Friction Coefficient 50%
• Surface Morphology 50%
• Dislocation Mechanism 50%
• Oxidative Wear 50%
• Indentation 50%
• Release Process 50%
• Length Scale 50%
• Shear Strain 50%
• Delamination 50%
• Oxygen Content 50%
• Coefficient of Friction 50%
• Wear Resistance 50%

Material Science

• Crystal Defect 100%
• Crystal Structure 50%
• Shear Strain 50%
• Wear Debris 50%
• Wear Resistance 50%
• Delamination 50%
• Surface Morphology 50%
• Dislocation Structure 50%
• Indentation 50%
• Point Defect 50%
• Dislocation Mechanism 50%